Vision-admittance-based adaptive RBFNN control with a SMC robust compensator for collaborative parallel robots

This paper proposes a novel vision -admittance -based adaptive neural network control method for collaborative parallel robots tracking a predefined trajectory and force command. First of all, the vision -admittance model is creatively developed for coupling visual information and force -sensing information in the image feature space and is applied to generate the image feature reference trajectory online according to the desired trajectory and the command of the interaction force. Secondly, considering the system modelling uncertainties and external disturbances, an adaptive Radial basis functions neural network (RBFNN) controller is created to realize high -precision trajectory tracking. The adaptive tuning laws are designed based on the Lyapunov stability theorem so that the entire system's stability and the convergence of the weight adaptation can be guaranteed. Moreover, a sliding mode control (SMC)-based robust compensator is added to the RBFNN controller as an auxiliary term to improve the robustness and stability of the control system. Finally, co -simulations between ADAMS/Simulink are performed on a collaborative Five -bar parallel robot to demonstrate the efficacy of the proposed controller.